Uncertainty Workshop: Overview of uncertainty factors in HTGHPs

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Uncertainty Workshop: Overview of uncertainty factors in HTGHPs EMRP Final Stakeholder Meeting NPL, Teddington, United Kingdom 1

DIN/EU Standards for GHPs ISO 830:1991 Thermal insulation Determination of steady-state thermal resistance and related properties Guarded hot plate apparatus EN 1946-:1999 Thermal performance of building products and components - Specific criteria for the assessment of laboratories measuring heat transfer properties - Part : Measurements by the guarded hot plate method EN 1664:001 Thermal performance of building materials and products - Determination of thermal resistance by means of guarded hot plate and heat flow meter methods - Dry and moist products with medium and low thermal resistance EN 1667:001 Thermal performance of building materials and products - Determination of thermal resistance by means of guarded hot plate and heat flow meter methods - Products of high and medium thermal resistance EN 1939:001 Thermal performance of building materials and products - Determination of thermal resistance by means of guarded hot plate and heat flow meter methods - Thick products of high and medium thermal resistance CEN/TS 15548-1:014 Thermal insulation products for building equipment and industrial installations - Determination of thermal resistance by means of the guarded hot plate method - Part 1: Measurements at elevated temperatures from 100 C to 850 C

Guarded Hot-Plate apparatus Working equation for two-specimen apparatus: Φ d ( Tm ) with T ( c A( T T ) ) / m Th T h c 3

Uncertainty assessment According to the Guide to the Expression of uncertainty in Measurement (GUM) Ideal model: Combined standard uncertainty of heat conductivity 4 ) ( ) ( ) ( 1 i N i i c x u x x u ) :,,,, ( ) ( c A T h T Φ d x ) ( ) ( c h m T T A d Φ T

Real model, e.g., HTGHP LNE1 ( T m ) ( T A HP, 1 TCP,1) ( THP, TCP,) d 1 HPGRimbalance Φ d S EG imbalance TCR THP,1 TCP,1 T Tm 4 U heat U res Φ junct Rres ( Tres ) A 1 HP T HP T0 d d 1 ( T T 0 d m HP, 0 T ) l CP, HP T l T 0 GR 0 U U R l l HP GR junct heat res res HP :resistanceof standardresistor : : : powerdissipatio nof junctions : voltageof hea tingwi re voltageof standardresistor : therma lexpansion coefficient of hotplate lengthof hotplate :innerlengthof guardring : therma lexpansion coefficient of sample d 5

Uncertainty sources 1) Equipment related uncertainties: a) Specimen thickness b) Metering area c) Temperature difference across specimen d) Input power of the hot plate e) Miscellaneous uncertainty sources ) Specimen related uncertainties: a) Absolute mean temperature b) Miscellaneous uncertainty sources 6

1a) Specimen thickness Measurement at room temperature outside GHP (with e.g. calliper, straight edge, feeler gauge): Calibration of instrument(s) Resolution of instrument(s) Drift of instrument(s) In-situ measurement inside GHP with laser displacement sensor: Calibration of instrument Resolution of instrument Fitting error of the calibration of laser displacement error Drift of instrument Influence of ambient conditions on instrument Thermal expansion of GHP (e.g., plates) Reproducibility of thickness measurement Variation in sample thickness Effect of pressure applied to the sample 7

1a) Specimen thickness Corrections for thermal expansion: Thermal expansion coefficient Mean sample temperature (T 0, T) Thermal expansion of spacer blocks (for compressible materials) Effect of pressure applied to the sample (for compressible materials) Variation of thickness with pressure (for compressible materials) Miscellaneous uncertainty factors: Operator effect (including vertical misalignment; variation in reading from different operators, noises on results) Temperature effect Effect of pressure load for double specimen GHP 8

1b) Metering area Dimension measurement at room temperature (diameter of hot plate, inner diameter of guard ring): Calibration of calliper Resolution of calliper Drift of calliper Operator effect (including misalignment, repeatability of the measurement) Corrections for thermal expansion: Thermal expansion coefficient of hot plate Thermal expansion coefficient of guard ring Mean temperature of hot plate (T 0, T) Mean temperature of guard ring (T 0, T) 9

1c) Temperature drop across specimen Uncertainties of digital voltmeter (dvm): Calibration of dvm Resolution of dvm Drift of dvm Uncertainties of thermocouples (tcs): Calibration of tcs: Calibration of the standard temperature sensor Drift of the standard temperature sensor Isothermal conditions when calibrating sensors Noises on results of calibration Electrical connections (parasitical emf) Cold junction temperature Response model used for each sensor 10

1c) Temperature drop across specimen Uncertainties of thermocouples (tcs): Interpolation error of tcs Spread of tcs from fitting curves (differences between tcs) Drift of each sensor Noise of each temperature result (repeatability) Temperature stability (variation with time) Parasitic voltages (connections, switches) Homogeneity of tc (along the sensor) Heat conduction of tc stem Installation, position of tcs Homogeneity: Temperature spread across metering area Temperature spread across the heated cold plate 11

1d) Input power of the hot plate Uncertainties of voltage measurement with digital voltmeter (dvm): Calibration of dvm Resolution of dvm Drift of dvm Repeatability, noises Corrections due to conditions differing from those of calibration Electrical connections Uncertainties of current measurement with digital voltmeter (dvm): Calibration of dvm Resolution of dvm Drift of dvm Repeatability, noises Corrections due to conditions differing from those of calibration Electrical connections 1

1d) Input power of the hot plate Uncertainties of resistor measurement: Calibration of standard (shunt) resistor Drift of shunt resistor Corrections due to conditions differing from those of calibration Uncertainties due to resistance of cold ends (for cable heaters): Length of wire in metering area Total length of heater wire Resistance of heating element/wires Effect of electrical resistance between metering heater and lateral guard heater Impedance of electrical insulation (for high T) Stability of power source 13

1e) Miscellaneous uncertainties Lateral heat flow across gap between main heater and guard ring due to temperature imbalance (centre-guard imbalance) Edge heat losses at gap between main heater and guard ring (influence of gap content) Heat transfer (conduction, convection, radiation) at lateral edges of specimen at transition to gap and/or edge guard For single-specimen GHPs: heat transfer between metering and auxiliary area Deviation from steady state conditions (thermal equilibrium) Flatness of heater plates Emissivity of heater plates Repeatability, reproducibility of thermal conductivity measurement (dispersion of results) 14

) Specimen related uncertainties a) Absolute mean temperature: Calibration of tcs Spread of tcs from fitting curves Resolution of dvm Calibration uncertainty of the PRT Calibration of dvm Interpolation error of tcs 15

) Specimen related uncertainties b) Miscellaneous uncertainty sources: For porous samples: effective thermal conductivity = thermal conductivity of solid material, gas-filled pores temperature-dependent thermal conductivity For porous, (semi-)transparent samples: effective thermal conductivity = thermal conductivity of solid material, gas-filled pores, radiation temperature-dependent thermal conductivity Inhomogeneity of specimen For two-specimen GHPs: Non-identical specimens Thermal contact resistance between specimen and plates Thermal contact resistance between specimen and thermocouples 16

Example: HTGHP LNE1, HDCaSi Uncertainty source Percentage of overall uncertainty at 650 C Metering area 1 1 Thickness of specimens 1 1 Repeatability, reproducibility 4 5 Power supplied to metering heater 6 5 Thermal contact resistance 8 19 Temperature imbalance between specimen and edge guard 14 7 Temperature difference across specimens 4 1 Temperature imbalance between metering heater and guard ring 41 49 Percentage of overall uncertainty at 150 C 17

Example: HTGHP LNE1, HDCaSi 18

Conclusions Uncertainties with lowest influence: Specimen thickness Metering area Most prominent uncertainty: Temperature imbalance between metering heater and guard ring Increasing uncertainties with increasing temperature: Temperature drop across specimen Temperature imbalance between specimen and edge guard Input power of metering heater Decreasing uncertainty with increasing temperature: Thermal contact resistance 19

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